一作/通讯论文：

[37] Yi Jianchen, Fu Ruicheng, Wei Yuan, and Hu Yingchao. From low-cost mineral to high-performance Li4SiO4 for solar energy storage and CO2 capture. 

Separation and Purification Technology, 2025. 354: 129050.

[36] Fu Ruicheng, Xu Bin, Yi Jianchen, and Hu Yingchao. Al-doped Li4SiO4 for cyclic solar energy storage and CO2 capture: An experimental and DFT study. 

Separation and Purification Technology, 2025. 354: 128621.

[35] Xu Bin, Fu Ruicheng, Liu Yujie, and Hu Yingchao. Fabrication of CaO pellets via polyvinyl alcohol (PVA) method for efficient CO2 capture and solar 

energy storage. Separation and Purification Technology, 2024. 335: 126135.（高被引论文）

[34] Liu Ding, Hu Yingchao, Feng Qiannian, and Fu Ruicheng. Synthesis of spherical CaO pellets incorporated with Mg, Y, and Ce inert carriers for CO2 capture. 

Environmental Science and Pollution Research, 2024.

[33] Feng Qiannian, Hu Yingchao, Liu Ding, and Fu Ruicheng. Incorporation of CaZrO3 into calcium-based heat carriers for efficient solar thermochemical 

energy storage. Solar Energy Materials and Solar Cells, 2024. 266: 112700.

[32] Hu Yingchao, Lu Hongyuan, Lv Zhe, Zhang Ming, and Yu Ge. Pore reconstruction mechanism of wheat straw-templated Li4SiO4 pellets for CO2 capture. 

Science of The Total Environment, 2023. 856: 159275.

[31] Hu Yingchao, Chen Yingjie, Fu Ruicheng, Yan Shuiping, and Li Hailong. Steam reactivation of spent CaO/CaCO3 for thermochemical energy storage. 

Solar Energy, 2023. 255: 138-145.

[30] Fu Ruicheng, Yu Ge, Cheng Junna, Hu Yingchao, and Yan Shuiping. One-step synthesis of porous Li4SiO4 pellets by polyvinyl alcohol (PVA) method 

for CO2 capture. Fuel, 2023. 331: 125873.

[29] Fu Ruicheng, Huang Jingchun, Feng Qiannian, Liu Ding, and Hu Yingchao. Synthesis of dark Li4−3xFexSiO4 for simultaneous direct solar thermal 

conversion and durable thermochemical energy storage. Journal of Energy Storage, 2023. 73: 109053.

[28] Fu Ruicheng, Hu Yingchao, and Wang Wenxia. Peering into the mechanisms of granulation and CO2 capture on alginate-assisted Li2CaSiO4-decorated 

Li4SiO4 sorbents. Chemical Engineering Journal, 2023. 477: 147156.

[27] Fu Ruicheng, Hu Yingchao, Wang Jinghao, Yu Ge, and Yan Shuiping. Organolithium-derived alkali-doped highly durable Li4SiO4 heat carrier for solar 

thermochemical energy storage. Solar Energy Materials and Solar Cells, 2023. 258: 112405.

[26] Hu Yingchao, He Weizhen, Cao Jixue, Cheng Guang, Fu Ruicheng, and Huang Long. Decorating CaO with dark Ca2MnO4 for direct solar thermal conversion 

and stable thermochemical energy storage. Solar Energy Materials and Solar Cells, 2022. 248: 111977.

[25] Hu Yingchao, Fu Ruicheng, Yu Ge, Cao Jixue, and Huang Jingchun. Scalable synthesis of Li4SiO4 sorbent from novel low-cost orthoclase mineral for CO2 

capture. Fuel, 2022. 324: 124492.

[24] Hu Yingchao; Ruicheng Fu; Wenqiang Liu; Dingding Yao; Shuiping Yan ; Lithium-based ceramics in nonsilicates for CO2 capture: current status and new trends, Journal of Materials Chemistry A, 2022, 10(4): 1706-1725.

[23] Hu Yingchao, Liu, Wenqiang,Yang Yuandong, Qu Mingyu, Li Hailong. CO2 capture by Li4SiO4 sorbents and their applications: Current developments and new trends. Chemical Engineering Journal 2019; 359:604–625.（热点论文）
[22] Hu Yingchao, Liu Wenqiang, Sun Jian, Li Mingkui, Yang Xinwei, Zhang Yang, Xu Minghou. Incorporation of CaO into novel Nd2O3 inert solid support for high temperature CO2 capture. Chemical Engineering Journal 2015; 273:333-343.（高被引论文）
[21] Hu Yingchao, Guo Yafei, Sun Jian, Li Haiong, Liu Wenqiang. Progress in MgO sorbents for cyclic CO2 capture: a comprehensive review. Journal of Materials Chemistry A. 2019;7(35):20103-20120.
[20] Hu Yingchao, Lu Hongyuan, Liu Wenqiang,Yang Yuandong, Li Hailong. Incorporation of CaO into inert supports for enhanced CO2 capture: A review. Chemical Engineering Journal 2020; 396:125253. 
[19] Hu Yingchao, Lu Hongyuan, Li Hailong. Single step fabrication of spherical CaO pellets via novel agar-assisted moulding technique for high-temperature CO2 capture. Chemical Engineering Journal 2021, 404:127137. 
[18] Li Hailong, Qu Mingyu, Yang Yuandong, Hu Yingchao*, Liu Wenqiang. One-step synthesis of spherical CaO pellets via novel graphite-casting method for cyclic CO2 capture. Chemical Engineering Journal. 2019;374:619-625. 
[17] Li Hailong, Qu Mingyu, Hu Yingchao*. Preparation of spherical Li4SiO4 pellets by novel agar method for high-temperature CO2 capture. Chemical Engineering Journal. 2020;380:122538. 
[16] Hu Yingchao, Liu Wenqiang, Wang Wenyu, Sun Jian, Yang Xinwei, Chen Hongqiang, Xu Minghou. Investigation of novel naturally occurring manganocalcite for CO2 capture under oxy-fuel calcination. Chemical Engineering Journal 2016; 296:412-419. 
[15] Hu Yingchao, Liu Wenqiang, Sun Jian, Li Mingkui, Yang Xinwei, Zhang Yang, Liu Xiaowei, Xu Minghou. Structurally improved CaO-based sorbent by organic acids for high temperature CO2 capture. Fuel 2016; 167:17-24.（热点论文）
[14] Hu Yingchao, Qu Mingyu, Li Hailong, Yang Yuandong, Yang Jianping, Qu Wenqi, Liu Wenqiang. Porous extruded-spheronized Li4SiO4 pellets for cyclic CO2 capture. Fuel 2019; 236:1043–1049.（高被引论文）
[13] Hu Yingchao, Liu Lei, Liu Wenqiang, Zhou Zijian, Structurally improved Li4SiO4 sorbents derived from lithium salicylate precursor for enhanced CO2 capture, Fuel Processing Technology. 2021, DOI: 10.1016/j.fuproc.2022.107027. 
[12] Li Hailong, Qu Mingyu, Hu Yingchao*. High-temperature CO2 capture by Li4SiO4 adsorbents: Effects of pyroligneous acid (PA) modification and existence of CO2 at desorption stage. Fuel Processing Technology. 2020;197:106186.

[11] H. Li, Y. Hu*, H. Chen, M. Qu, Porous spherical calcium aluminate-supported CaO-based pellets manufactured via biomass-templated extrusion–spheronization technique for cyclic CO2 capture, Environmental Science and Pollution Research, 26 (2019) 21972-21982.
[10] Hu Yingchao, Liu Wenqiang, Chen Hongqiang, Zhou Zijian, Wang Wenyu, Sun Jian, Yang Xinwei, Li Xian, Xu Minghou. Screening of inert solid supports for CaO-based sorbents for high temperature CO2 capture. Fuel 2016; 181:199-206.
[9] Hu Yingchao, Liu Xiaowei, Zhou Zijian, Liu Wenqiang, Xu Minghou. Pelletization of MgO-based sorbents for intermediate temperature CO2 capture. Fuel 2017; 187:328-337. 
[8] Hu Yingchao, Liu Wenqiang, Peng Yang, Yang Yuandong, Sun Jian, Chen Hongqiang, Zhou Zijian, Xu Minghou. One-step synthesis of highly efficient CaO-based CO2 sorbent pellets via gel-casting technique. Fuel Processing Technology 2017; 160:70-77. 
[7] Hu Yingchao, Liu Wenqiang, Sun Jian, Yang Xinwei, Zhou Zijian, Zhang Yang, Xu Minghou. High temperature CO2 capture on novel Yb2O3-supported CaO-based sorbents. Energy & Fuels 2016; 30:6606-6613.
[6] Hu Yingchao, Liu Wenqiang, Zhou Zijian, Yang Yuandong. Preparation of Li4SiO4 sorbents for carbon dioxide capture via a spray-drying technique. Energy & Fuels 2018; 32:4521-4527.
[5] H. Li, Y. Chen, L. Leng, Y. Hu*, Thermochemical Energy Storage of Concentrated Solar Power by Novel Y2O3-Doped CaO Pellets, Energy & Fuels, 35 (2021) 12610-12618.
[4] Hu Yingchao, Lu Hongyuan, Li,Hailong. Li4SiO4 pellets templated by rice husk for cyclic CO2 capture: Insight into the modification mechanism, Ceramics International 2021, DOI: 10.1016/j.ceramint.2021.08.095.
[3] Hu Yingchao, Liu Wenqiang, Yang Yuandong, Tong Xianliang, Chen Q Zhou Zijian. Synthesis of highly efficient, structurally improved Li4SiO4 sorbents for high-temperature CO2 capture. Ceramics International 44 (2018) 16668–16677. 
[2] Hu Ying-chao, Liu Wen-qiang, Yang Yuan-dong, Sun Jian, Zhou Zi-jian, Xu Ming-hou. Enhanced CO2 capture performance of limestone by industrial waste sludge. Chemical Engineering & Technology 2017; 40:2322-2328.
[1] Zhang Yang, Liu Wenqiang*, Yang Xinwei, Sun Jian, Hu Yingchao*, Xu Minghou. Incorporation of CaO in inert solid matrix by spray drying sol mixture of precursors. RSC Advances 2016; 6:57658-57666.

授权发明专利

[6] 胡迎超，付瑞诚，一种Li2CaSiO4修饰型Li4SiO4基球形CO2吸附剂、制备方法及其应用，国家发明专利. 专利号：ZL 202310922303.8. 

[5] 胡迎超，付瑞诚，一种球形Li4SiO4基CO2吸附剂的制备方法，国家发明专利. 专利号：ZL 202210979378.5.

[4] 胡迎超，李海龙，渠明玉，屈文麒，杨建平，一种球形Li4SiO4基CO2吸附剂的制备方法，国家发明专利. 专利号：ZL 201910720523.6.

[3] 胡迎超，刘文强，徐明厚，杨新伟，孙健，王文煜，陈洪强. 一种钙基CO2吸附剂及其制备方法. 国家发明专利. 专利号：ZL 201510788245.X. 
[2] 胡迎超，刘文强，徐明厚，孙健，杨新伟，王文煜，陈洪强, 一种球状钙基CO2吸附剂的制备方法, 国家发明专利. 专利号: ZL 201610368182.7. 
[1] 胡迎超，刘文强，徐明厚，杨新伟，孙健，王文煜，陈洪强. 一种镱掺杂的CO2吸附剂及其制备方法, 国家发明专利. 专利号: ZL 201510922931.1.

授权实用新型专利
[1] 胡迎超，李海龙，杨建平，屈文麒，渠明玉，鹿红媛，陈英杰，一种钙基二氧化碳吸附剂的造粒成型装置，实用新型专利. 专利号：ZL 201921540632.1. 
[2] 胡迎超，李海龙，杨建平，屈文麒，一种用于高温二氧化碳吸附剂的流化热态磨损测试装置，实用新型专利. 专利号：ZL 201921629310.4. 
[3] 胡迎超，李海龙，吸附剂颗粒磨损测试装置, 实用新型专利. 专利号: ZL 201921629203.1.

国际会议论文：
[1] Hu Yingchao. Synthesis of spherical Li4SiO4 pellets for high-temperature CO2 capture. 2019 International Symposium on Environmental Science and Technology, Hangzhou, China, Sept. 25-28, 2019. (邀请报告).
[2] Hu Yingchao, Li Hailong. Porous extruded-spheronized Li4SiO4 pellets via mi-crocrystalline cellulose templating for CO2 capture, The 3rd International Conference on Bioresources, Energy, Environment and Materials Technology, Hong Kong, Jun 12-15 2019.
[3] Hu Yingchao, Liu Wenqiang, Yang Yuandong, Yao Shun, Xu Minghou. Preparation of Li4SiO4 Sorbents for Carbon Dioxide Capture via a Spray-Drying Technique, 6th Sino-Australian Symposium on Advanced Coal and Biomass Utilisation Technologies, Perth, Western Australia. Dec 4-8 2017.
[4] Hu Yingchao, Liu Wenqiang, Xu Minghou. Enhanced performance of limestone by industrial waste sludge for post-combustion CO2 capture. 8th International Symposium on Multiphase Flow, Heat Mass Transfer and Energy Conversion, Chengdu, China. Dec 16-19, 2016.